KR200340357Y1 - Digging structure of a ground pipe - Google Patents

Abstract

The present invention is an excavation hole formed by drilling a predetermined diameter and a predetermined depth in the ground; A lower bentonite part which is hollowed to be in contact with a lower surface of the lower end of the excavation hole; A ground copper tube rod including a hollow cylindrical body, a tip needle formed at a lower end of an excavation hole so as to have a structure seated and pressed on the ground, and a copper tube terminal configured to be connected to a grounding conductor installed in the structure; A ground reducing agent introduced into the excavation hole; An upper bentonite part flowing into the upper end of the drilling hole by a predetermined depth from the ground reducing agent injected into the drilling hole; The present invention relates to a coring excavation structure of a ground copper pipe rod, comprising a cover installed at an uppermost end of an excavation hole. Maintains the specified ground resistance value to prevent loss to the soil layer, prevent groundwater from entering the excavation hole, and to increase the adhesion coefficient between the ground reducer and the soil to have a low ground resistance value. To quickly release various lightning and surges. In addition, even if only a few ground copper tube rods are constructed, the prescribed ground resistance value is satisfied, so that the construction area can be reduced, thereby reducing the occurrence of civil complaints and reducing costs. In addition, through the additional configuration with a test box there is an effect that can be managed from time to time by installing a test terminal box for the cover to check the change in the ground resistance value in the future.

Description

Digging structure of a ground pipe}

The present invention effectively disperses high voltage currents generated by external factors such as ground faults or lightning strikes occurring inside the power system to the ground, thereby preventing various electronic devices such as communication devices and radar devices from being damaged by reverse flashover. The present invention relates to a coring excavation structure of a grounding copper rod.

Lightning strikes are a phenomenon in which huge electric energy generated by energizing air flow, such as static electricity, is discharged to the surface of the earth. These lightning strikes have tremendous destructive power, so when installing various facilities, be sure to equip the grounding device to discharge the current quickly to the ground when lightning strikes to prevent damage caused by lightning strikes. At this time, since the earth is like a capacitor having a large capacity, even if a current such as a lightning strike can be sufficiently absorbed, a phenomenon such as a potential rise does not occur.

Grounding is generally buried in the ground, and the current applied to the grounding pole is caused by surges such as external lightning strikes, fault currents caused by failures in the power system and electrical equipment, and unbalanced currents caused by three-phase unbalance. have. This current needs to be quickly radiated to ground through the ground electrode.

The grounding device generally used consists of a grounding wire connected to the grounding pole in a building and steel structure that is concerned with lightning damage.In particular, a lightning rod is installed at the top of the building and the lightning rod is connected by copper wire. Grounding structure is most widely used.

1 shows a coring excavation structure of a conventional ground rod.

For example, a distribution pole in which the overhead processing line 8 and the lightning arrester 10 are installed, as shown in the drawing, is connected to a grounding rod 4 connected to the grounding conductor 6 installed in the distribution pole and embedded in the ground. Has However, when the ground rod is buried in a terrain with high earth resistivity, air gaps are formed between the ground rod and soil, so that the ground rod is less than the prescribed ground resistance value. Therefore, a plurality of ground rods are distributed to the ground to lower the ground resistance. The method of increasing the discharge effect of was used. However, the above method may encounter unexpected obstacles due to the problem of occupying a large land area, and when the grounding rod is placed on the ground surface of a concrete pavement or an adjacent road, water, gas pipes, power lines, and telephone lines. There is a risk of damage to cables, etc. Also, because paved roads and sidewalk blocks must be dug up, the excavation and recovery costs are excessive, and the work is very difficult, and the ground resistance is not displayed after construction. There is a problem that can not check and check the changes from time to time.

The present invention was devised to solve the above problems. Bentonite is a retention material that prevents the occurrence of foreign substances and chemical reactions around the ground copper tube rod buried underground with the ground reducing agent and prevents the variation of the ground resistance value. By embedding together, so that even if only a few ground copper rods are buried, they can have a high grounding resistance value, and provide a coring excavation structure of the ground copper tube rods including a test box that can check and check ground changes from time to time. The purpose is.

1 shows a coring excavation structure of a conventional ground rod.

Figure 2 shows an embodiment of the coring excavation structure of the ground copper tube rod according to the present invention.

Figure 3 shows a coring excavation method of the ground copper tube rod according to the present invention.

Figure 4 shows the state after the completion of the coring excavation process of the ground copper tube rod according to the present invention.

Figure 5 shows the appearance after the completion of the coring excavation process of the ground copper tube rod including the test box according to the present invention.

6 is an exploded perspective view of a test box according to the present invention.

7 is a perspective view showing the shape of the ground copper tube rod according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: ground copper tube rod 101: filling hole

105: copper tube terminal 102: lower bentonite part

103: tip needle 104: upper bentonite part

106: ground reducing agent 110: grounding conductor

112: lightning arrester 114: processing ground wire

116: roasting pole 120: inlet

122: protection means 124: ground fuselage

130: earth 140: test box

141: ground test terminal 142: cover

144: protective concrete 145: handle

146: protection cylinder 148: flange

Coring excavation structure of the grounding copper tube rod according to the present invention for achieving the above object is an excavation hole formed by drilling a predetermined diameter and a predetermined depth in the ground; A lower bentonite part which is hollowed to be in contact with a lower surface of the lower end of the excavation hole; A ground copper tube rod including a hollow cylindrical body, a tip needle formed at a lower end of an excavation hole so as to have a structure seated and pressed on the ground, and a copper tube terminal configured to be connected to a grounding conductor installed in the structure; A ground reducing agent introduced into the excavation hole; An upper bentonite part flowing into the upper end of the drilling hole by a predetermined depth from the ground reducing agent injected into the drilling hole; It characterized in that it comprises a cover installed on the top end of the excavation hole.

In addition, the coring excavation structure of the ground copper rod, may include a test box on the upper bentonite part, the test box, the test box, the ground test terminal connected to the ground lead passing through the upper bentonite part; A protective cylinder configured to include a protective concrete introduced into an excavation hole, or having a flange portion formed on an inner wall and supported on the upper bentonite portion; A ground test terminal connected to the ground lead passing through the upper bentonite part; It is configured to include a protective concrete that is introduced into the protective cylinder and seated on the flange portion.

In addition, the ground copper tube rod is provided with one or more filling holes to be penetrated through the tube wall.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 shows an embodiment of the coring excavation structure of the ground copper tube rod according to the present invention.

As shown, the ground conductor 110 is connected to the processing ground line 114 and the arrester 112 provided in the distribution pole 116, the ground conductor 110 is a ground copper embedded in the ground 130 It is connected to the tube 100. The lower bentonite part 102 is buried at the lower end of the excavation hole 50 to form the soil to have a predetermined depth below the ground, and the lower bentonite part 102 may be inserted into the ground copper tube rod 100. The interior is hollow so that it is constructed. A ground copper rod (100) is placed on the bottom surface of the lower bentonite portion (102) for crimping and seating with a crimping tool twice, and the ground reduction between the ground copper tube rod (100) and the inner side of the lower bentonite portion (102) is reduced. The first 106 are spaced apart from each other so that they can be introduced.

The bentonite is a clay containing montmorillonite, and includes quartz, feldspar, zeolite, and the like. Generally, the bentonite is swelled by adsorbing water. It is also used as the main component of yisu, the binder of casting molds, the mixing agent of ceramic raw materials, and the base of ointment.

The reason for using bentonite in the present invention is that the ground reducing agent 106 injected into the excavation hole 50 is lost to the underground soil layer, and the ground water is prevented from entering the excavation hole 50. In order to increase the adhesion coefficient between the ground reducing agent 106 and the soil, it is to have a low ground resistance value.

In addition, the ground reducing agent 106 introduced into the excavation hole 50 and filled between the lower bentonite part 102 and the upper bentonite part 104 is a kind of filler and has excellent grounding effects such as Sanus or conductive concrete. Use molten material.

Figure 3 shows a coring excavation method of the ground copper tube rod according to the present invention.

First, a drilling hole 50 having a predetermined diameter and depth is installed on the ground, and a molten bentonite is applied to the lower portion of the drilling hole 50 to form a hollow cylindrical structure. After the above process, the ground copper tube rod 100 connected to the grounding conductor 110 is pressed and seated at the bottom of the excavation hole 50, and when the ground reducing agent 106 is injected, the protection to protect the excavation hole 50 from collapsing. The ground reducing agent 106 is injected through the injection hole 120 using a coring press (not shown) while the means 122 is inserted into the upper end of the excavation hole 50. The coring presser (not shown) is a tool for applying pressure so that the grounding reducing agent 106 is closely adhered to the grounding copper rod 100 and the lower bentonite portion 102, and the grounding copper rod 100 and the grounding reducing agent A gap is generated between the 106 to prevent the grounding resistance from increasing.

Figure 4 shows the state after the completion of the coring excavation process of the ground copper tube rod according to the present invention.

3, the protection means 122 and the injection hole 120 are removed from the excavation hole 50, and bentonite is injected into the portion to form the upper bentonite part 104, which is a ground reducing agent 106. It is a means for preventing foreign matter from entering into the inside, and preventing a rise in the value of the ground resistance due to the chemical reaction of the ground reducing agent 106 caused by the foreign matter, and the cover 142 provided at the top of the excavation hole 50. Prevents loss and damage of the upper bentonite part. By completing the process as shown in Figure 4, a ground body 124 is configured to ensure a stable ground resistance value is not significantly affected by changes in seasons, climate and surrounding environment.

Figure 5 shows the appearance after the completion of the coring excavation process of the ground copper tube rod including the test box according to the present invention.

A protective cylinder 146 having a cylindrical shape on the upper bentonite portion and having a flange portion 148 formed therein is seated therein, and a flange portion formed inside the protective cylinder 146 by being introduced into the protective cylinder 146 ( The protective concrete 144 is seated on the 148, and the cover 142 is covered at the top of the excavation hole 50 to cover the protective concrete 144 and the protective cylinder 146.

On the other hand, the grounding conductor 110 is separated into two branches, one of which enters a distribution pole and the other of which penetrates into the upper bentonite part and is connected to the grounding test terminal 141, where the grounding test terminal 141 is shown. As described above, there is a method of attaching and installing the inside of the protective cylinder 146, or a method of installing in a free state where there is no restriction.

The purpose of the test box 140 as described above is to simply open the cover 142, lift the protective concrete 144 from the protective cylinder 146 or the excavation hole 50, and then remove the ground test terminal 141. It is to check the abnormality of the ground changes through at any time, the protective concrete 144 having a certain weight is installed so that children or a specific person can not open the cover 142 and touch the test ground wire. The cover 142 is usually made of a material using cast iron when the excavation hole 50 is installed on the roadway, and is formed of a material usually using P.V.C when the excavation hole 50 is installed in a sidewalk or a flower bed. And the upper end of the protective concrete 144 is provided with a handle 145 to facilitate lifting.

On the other hand, the protective cylinder 146 is to prevent the soil of the excavation hole 50 wall collapse, support the protective concrete 144, to create a space that can protect the ground test terminal 141 The support concrete 144 is supported on the upper bentonite part without the protection cylinder 146, and the ground conductor 110 and the ground test terminal 141 are spaced between the protection concrete 144 and the wall of the excavation hole 50. Test box 140 can be configured even if pulled out as is optionally installed.

6 is an exploded perspective view of a test box according to the present invention.

As shown, a protective concrete 144 having a handle 145 is introduced into the protective cylinder 146 and a cover 142 covering the protective cylinder 146 and the protective concrete 144 is located at the top. Has

7 is a perspective view showing the shape of the ground copper tube rod according to the present invention.

As shown, the grounding copper rod 100 has a cylindrical body hollowed out to allow the ground reducing agent 106 to flow therein, which is a means for the grounding body 124 to have a better grounding resistance. Are utilized.

In addition, the ground copper tube rod 100 has at least one filling hole 101 penetrating the inside and outside of the ground copper tube rod 100, the filling hole 101 is introduced into the ground copper tube rod 100 It also serves to prevent the formation of voids in the ground reducing agent 106, and to increase the adhesion strength when the ground reducing agent 106 is cured.

When the ground copper tube rod 100 is squeezed and buried in the bottom of the excavation hole 50, the lower end of the ground copper tube rod 100 has an end in order to facilitate the pulling and to increase the radiation amount of current at the bottom. The tip needle part 103 formed in the shape of this narrowing triangular pyramid is provided.

In addition, the ground copper tube rod 100 is provided with a copper tube terminal 105 so that the ground conductor 110 can be connected to the lightning arrester 112 and the processing ground line 114 shown in FIG.

Coring excavation structure of the ground copper tube bar according to the present invention, by using the bentonite at the lower end and the upper end of the drilling hole, to prevent the ground reducing agent injected into the excavation hole to be lost to the underground soil layer, and groundwater flows into the excavation hole It is prevented from being made and increases the adhesion coefficient between the earth reducer and the soil so as to have a low ground resistance value, so that various lightning and surges can be released quickly by maintaining the prescribed ground resistance value. In addition, even if only a few ground copper tube rods are installed, the ground resistance value is satisfied. Therefore, the construction area can be reduced, thereby reducing civil complaints and reducing costs. The effect is to check for changes.

Claims (5)

An excavation hole 50 formed in the ground 130 by drilling a predetermined diameter and a predetermined depth; A lower bentonite part 102 formed to be hollow so as to be in contact with a lower surface of the lower end of the excavation hole 50; A hollow tubular terminal configured to be connected to a hollow cylindrical body, a tip needle 103 formed at a lower end of the excavation hole 50 so as to have a structure that is compressed and seated on the ground, and a grounding conductor 110 installed in the structure. A ground copper tube rod (100) comprising a 105; A ground reducing agent (106) flowing into the excavation hole (50); An upper bentonite part 104 flowing into the upper end of the drilling hole 50 by a predetermined depth from the ground reducing agent injected into the drilling hole 50; A cover 142 installed at an uppermost end of the excavation hole 50; Coring excavation structure of the grounding copper rods, characterized in that comprising a. The method of claim 1, Coring excavation structure of the ground copper tube rod, And a test box (140) on the upper bentonite part. The method of claim 2, The test box 140, A ground test terminal 141 connected to the ground lead 110 passing through the upper bentonite part; Coring excavation structure of the grounding copper tube rod, characterized in that it comprises a protective concrete 144 introduced into the excavation hole (50). The method of claim 2, The test box 140, A protection cylinder 146 supported on the upper bentonite part and having a flange part 148 formed on an inner wall thereof; A ground test terminal 141 connected to the ground lead 110 passing through the upper bentonite part; Coring excavation structure of the grounding copper rod, characterized in that it comprises a protective concrete 144 is inserted into the protective cylinder 146 and seated on the flange 148. The method according to any one of claims 1 to 4, The ground copper tube rod 100, Coring excavation structure of the ground copper tube rod, characterized in that provided with at least one filling hole 101 to be penetrated through the pipe wall.